Pawel Keblinski

26.2k total citations · 8 hit papers
210 papers, 20.6k citations indexed

About

Pawel Keblinski is a scholar working on Materials Chemistry, Biomedical Engineering and Atomic and Molecular Physics, and Optics. According to data from OpenAlex, Pawel Keblinski has authored 210 papers receiving a total of 20.6k indexed citations (citations by other indexed papers that have themselves been cited), including 162 papers in Materials Chemistry, 53 papers in Biomedical Engineering and 34 papers in Atomic and Molecular Physics, and Optics. Recurrent topics in Pawel Keblinski's work include Thermal properties of materials (79 papers), Carbon Nanotubes in Composites (37 papers) and Material Dynamics and Properties (32 papers). Pawel Keblinski is often cited by papers focused on Thermal properties of materials (79 papers), Carbon Nanotubes in Composites (37 papers) and Material Dynamics and Properties (32 papers). Pawel Keblinski collaborates with scholars based in United States, Italy and Germany. Pawel Keblinski's co-authors include Simon R. Phillpot, J. A. Eastman, Patrick K. Schelling, Soo-Chang Choi, David G. Cahill, William J. Evans, D. Wolf, Li‐Ping Xue, Sergei Shenogin and Tapan Desai and has published in prestigious journals such as Science, Proceedings of the National Academy of Sciences and Physical Review Letters.

In The Last Decade

Pawel Keblinski

207 papers receiving 20.0k citations

Hit Papers

align trajectories sort by overperformance

What are hit papers?

Hit papers significantly outperform the citation benchmark for their cohort. A paper qualifies if it has ≥500 total citations, achieves ≥1.5× the top-1% citation threshold for papers in the same subfield and year (this is the minimum needed to enter the top 1%, not the average within it), or reaches the top citation threshold in at least one of its specific research topics.

Mechanisms of heat flow in suspensions of nano-sized particles (nanofluids)

2002 1.8k citations Pawel Keblinski, Simon R. Phillpot et al. International Journal of Heat and Mass Transfer profile →
Nanoscale thermal transport. II. 2003–2012

2014 1.3k citations David G. Cahill, Paul V. Braun et al. profile →
Comparison of atomic-level simulation methods for computing thermal conductivity

2002 1.3k citations Patrick K. Schelling, Simon R. Phillpot et al. profile →
Interfacial heat flow in carbon nanotube suspensions

2003 910 citations David G. Cahill, Sergei Shenogin et al. profile →
Exact method for the simulation of Coulombic systems by spherically truncated, pairwise r−1 summation

1999 764 citations Pawel Keblinski, Simon R. Phillpot et al. The Journal of Chemical Physics profile →
Nanofluids for thermal transport

2005 761 citations Pawel Keblinski, David G. Cahill et al. profile →
THERMAL TRANSPORT IN NANOFLUIDS

2004 723 citations Simon R. Phillpot, Pawel Keblinski et al. profile →
Ultralow Thermal Conductivity in Disordered, Layered WSe ₂ Crystals

2006 709 citations David G. Cahill, Pawel Keblinski et al. Science profile →

Peers — A (Enhanced Table)

Peers by citation overlap · career bar shows stage (early→late) cites · hero ref

Name	h						Papers	Cites
Pawel Keblinski United States	67	13.1k	7.4k	5.4k	2.8k	2.4k	210	20.6k
Simon R. Phillpot United States	72	20.8k 1.6×	5.1k 0.7×	7.7k 1.4×	2.7k 1.0×	4.0k 1.7×	355	28.0k
David G. Cahill United States	87	24.4k 1.9×	6.4k 0.9×	4.2k 0.8×	7.2k 2.6×	8.0k 3.4×	384	34.2k
Chun Ning Lau United States	50	20.0k 1.5×	7.3k 1.0×	2.0k 0.4×	2.4k 0.8×	7.7k 3.2×	127	26.7k
Patrick E. Hopkins United States	64	11.3k 0.9×	2.0k 0.3×	2.9k 0.5×	3.2k 1.1×	3.6k 1.5×	364	15.1k
Alexander A. Balandin United States	85	35.4k 2.7×	8.9k 1.2×	4.0k 0.7×	5.6k 2.0×	12.7k 5.4×	416	43.8k
Wanlin Guo China	68	11.4k 0.9×	4.8k 0.7×	2.6k 0.5×	1.1k 0.4×	5.3k 2.2×	505	18.9k
Franz Faupel Germany	57	6.4k 0.5×	3.9k 0.5×	3.0k 0.6×	303 0.1×	4.1k 1.7×	423	13.4k
H. Gleiter Germany	76	21.9k 1.7×	3.2k 0.4×	15.4k 2.9×	412 0.1×	3.3k 1.4×	347	28.9k
Wenzhong Bao China	58	19.9k 1.5×	7.6k 1.0×	2.1k 0.4×	2.3k 0.8×	9.6k 4.1×	188	27.5k
Xianfan Xu United States	49	10.8k 0.8×	3.7k 0.5×	827 0.2×	783 0.3×	5.4k 2.3×	251	15.5k

Countries citing papers authored by Pawel Keblinski

Since Specialization

Citations

This map shows the geographic impact of Pawel Keblinski's research. It shows the number of citations coming from papers published by authors working in each country. You can also color the map by specialization and compare the number of citations received by Pawel Keblinski with the expected number of citations based on a country's size and research output (numbers larger than one mean the country cites Pawel Keblinski more than expected).

Fields of papers citing papers by Pawel Keblinski

Since Specialization

Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by Pawel Keblinski. Nodes represent research fields, and links connect fields that are likely to share authors. Colored nodes show fields that tend to cite the papers produced by Pawel Keblinski. The network helps show where Pawel Keblinski may publish in the future.

Co-authorship network of co-authors of Pawel Keblinski

This figure shows the co-authorship network connecting the top 25 collaborators of Pawel Keblinski. A scholar is included among the top collaborators of Pawel Keblinski based on the total number of citations received by their joint publications. Widths of edges represent the number of papers authors have co-authored together. Node borders signify the number of papers an author published with Pawel Keblinski. Pawel Keblinski is excluded from the visualization to improve readability, since they are connected to all nodes in the network.

All Works

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20 of 20 papers shown

Wasiucionek, M., et al.. (2025). Structural characterization of amorphous Bi 2 O 3 obtained by molecular dynamics simulation of melt quenching. Physica B Condensed Matter. 701. 416932–416932.

Sengupta, Bratin, Qiaobei Dong, Dinesh Behera, et al.. (2023). Carbon-doped metal oxide interfacial nanofilms for ultrafast and precise separation of molecules. Science. 381(6662). 1098–1104. 62 indexed citations

Ramanath, Ganpati, Geetu Sharma, Johan G. Alauzun, et al.. (2023). Engineering inorganic interfaces using molecular nanolayers. Applied Physics Letters. 122(26). 6 indexed citations

Ramanath, Ganpati, et al.. (2022). Viscoelastic bandgap in multilayers of inorganic–organic nanolayer interfaces. Scientific Reports. 12(1). 10788–10788. 5 indexed citations

Babaei, Hasan, et al.. (2021). Interfacial thermal conductance between multi-layer graphene sheets and solid/liquid octadecane: A molecular dynamics study. Journal of Energy Storage. 37. 102469–102469. 14 indexed citations

Ranganathan, Raghavan, et al.. (2019). Viscoelastic and dynamic properties of polymer grafted nanocomposites with high glass transition temperature graft chains. Journal of Applied Physics. 126(19). 8 indexed citations

Ranganathan, Raghavan, et al.. (2017). Viscoelastic and Dynamic Properties of Well-Mixed and Phase-Separated Binary Polymer Blends: A Molecular Dynamics Simulation Study. Macromolecules. 50(16). 6293–6302. 10 indexed citations

Ranganathan, Raghavan, et al.. (2015). Modeling high-temperature diffusion of gases in micro and mesoporous amorphous carbon. The Journal of Chemical Physics. 143(8). 84701–84701. 12 indexed citations

Ranganathan, Raghavan, Kiran Sasikumar, & Pawel Keblinski. (2015). Realizing tunable molecular thermal devices based on photoisomerism—Is it possible?. Journal of Applied Physics. 117(2). 4 indexed citations

10.

Babaei, Hasan, Pawel Keblinski, & J. M. Khodadadi. (2013). Improvement in thermal conductivity of paraffin by adding high aspect-ratio carbon-based nano-fillers. Physics Letters A. 377(19-20). 1358–1361. 66 indexed citations

11.

Losego, Mark D., et al.. (2011). Testing the minimum thermal conductivity model for amorphous polymers using high pressure. Bulletin of the American Physical Society. 2011. 1 indexed citations

12.

Hu, Lin, Tapan Desai, & Pawel Keblinski. (2011). Thermal transport in graphene-based nanocomposite. Journal of Applied Physics. 110(3). 92 indexed citations

13.

Şen, Sinan, et al.. (2007). Molecular underpinnings of the mechanical reinforcement in polymer nanocomposites (vol 40, pg 4059, 2007). Macromolecules. 40(13). 4732–4732. 2 indexed citations

14.

Watanabe, Taku, Boris Ni, Simon R. Phillpot, Patrick K. Schelling, & Pawel Keblinski. (2007). Thermal conductance across grain boundaries in diamond from molecular dynamics simulation. Journal of Applied Physics. 102(6). 45 indexed citations

15.

Kumar, Sanat K., et al.. (2007). Molecular Underpinnings of the Mechanical Reinforcement in Polymer Nanocomposites. Volume 40, Number 11, May 29, 2007, pp 4059−4067.. Macromolecules. 40(13). 4732–4732. 4 indexed citations

16.

Khare, Rajesh, Pawel Keblinski, & Arun Yethiraj. (2006). Molecular dynamics simulations of heat and momentum transfer at a solid–fluid interface: Relationship between thermal and velocity slip. International Journal of Heat and Mass Transfer. 49(19-20). 3401–3407. 65 indexed citations

17.

Prasher, Ravi, William J. Evans, Paul Meakin, et al.. (2006). Effect of aggregation on thermal conduction in colloidal nanofluids. Applied Physics Letters. 89(14). 338 indexed citations

18.

Garde, Shekhar, et al.. (2005). Thermal Resistance of Nanoscopic Liquid−Liquid Interfaces: Dependence on Chemistry and Molecular Architecture. Nano Letters. 5(11). 2225–2231. 95 indexed citations

19.

Danailov, Daniel M., Pawel Keblinski, Saroj K. Nayak, & Pulickel M. Ajayan. (2002). Bending Properties of Carbon Nanotubes Encapsulating Solid Nanowires. Journal of Nanoscience and Nanotechnology. 2(5). 503–507. 23 indexed citations

20.

Keblinski, Pawel, Amos Maritan, Flavio Toigo, R. Messier, & Jayanth R. Banavar. (1996). Continuum model for the growth of interfaces. Physical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics. 53(1). 759–778. 35 indexed citations

Rankless uses publication and citation data sourced from OpenAlex, an open and comprehensive bibliographic database. While OpenAlex provides broad and valuable coverage of the global research landscape, it—like all bibliographic datasets—has inherent limitations. These include incomplete records, variations in author disambiguation, differences in journal indexing, and delays in data updates. As a result, some metrics and network relationships displayed in Rankless may not fully capture the entirety of a scholar's output or impact.

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